Chicken Cardiac Muscle Research Articles

Properties of chicken cardiac dystrophin

We investigated the presence of dystrophin by immunoblot and immunofluorescence analyses, negative staining, rotatory shadowing and immunogold electron microscopy in chicken cardiac muscle. Saponin was found to be better than Triton X-100 for providing a new ‘dystrophin-enriched’ solution for use in biochemical studies of the molecule. By Western blot analysis, only a 400-kDa band was revealed with polyclonal antibodies directed against a central region (residues 1178–1723) of the dystrophin molecule and no cross-reactions with other proteins or degraded products were observed. Specific cleavage of the dystrophin molecule showed that the central rod-shaped domain corresponded to a resistant ‘core’. This structure might rigidify the protein. By immonofluorescence, dystrophin was localized at the periphery of cardiac ventricular cells. The molecule was examined by electron microscopy and found to have variable lengths (140–160 nm for the monomeric from and about 260 ± 10 nm or more for oligomeric forms). These oligomeric structures are considered to be associated molecules which are only partially overlapped lengthwise. The precise distribution of dystrophin within the cardiac muscle was determined by visualisation of gold particles in immuno-electron microscopy. Gold particles were found on the sarcolemma with no evidence of any association with cytoplasmic structures. The present data provide further details on the cardiac dystrophin molecule and suggest that its capacity of self-association may elasticize the dystrophin dimer.

Evidence on the participation of the 3',5'-cyclic AMP pathway in the non-genomic action of 1,25-dihydroxy-vitamin D 3 in cardiac muscle

Several studies have suggested that vitamin D plays a role in cardiovascular function. It has been recently shown that in vitro treatment of vitamin D-deficient chick cardiac muscle with physiological concentrations of 1,25-dihydroxy-vitamin D 3 (1,25(OH) 2D 3) induces a rapid (1–10 min) increase of tissue 45Ca uptake which can be suppressed by Ca channel blockers. The hormone simultaneously stimulated heart microsomal membrane protein phosphorylation. Experiments were performed to investigate the existence of a relationship between these changes and to obtain information about the mechanism involved in 1,25(OH) 2D 3-induced modifications in cardiac protein phosphorylation. Dibutyryl cyclic AMP (10 μM) and forskolin (10 μM), known activators of the cAMP pathway, produced time courses of changes in 45Ca uptake by chick heart tissue similar to 1,25(OH) 2D 3 (10 −10 M). Analogously to the hormone, the effects of both compounds were abolished by nifedipine (30 μM) and verapamil (10 μM). In agreement with these observations, 1,25(OH) 2D 3 significantly increased (34–70%) heart muscle cAMP levels within 1–10 min of treatment. In addition, 1,25(OH) 2D 3 and forskolin caused similar changes in cardiac microsomal membrane protein phosphorylation (e.g. stimulation in 43 kDa and 55 kDa proteins). These changes were also evidenced by direct exposure of isolated heart microsomes to 1,25(OH) 2D 3, suggesting a direct membrane action of the hormone. The fast effects of 1,25(OH) 2D 3 on dihydropyridine-sensitive cardiac muscle Ca uptake could be reproduced in primary-cultured myocytes isolated from chick embryonic heart. Furthermore, the effects of the hormone could be suppressed by a specific protein kinase A inhibitor. These results suggest that 1,25(OH) 2D 3 affects heart cell calcium metabolism through regulation of Ca channel activity mediated by the cAMP pathway.

Crystallization of mitochondrial creatine kinase. Growing of large protein crystals and electron microscopic investigation of microcrystals consisting of octamers.

Mitochondrial creatine kinase isolated from chicken cardiac muscle was crystallized by vapor diffusion techniques. Depending on the growth conditions, fine needles and platelets as well as large single crystals appeared after a few days. Large crystals were shown to diffract to at least 3.2 A resolution (Schnyder, T., Winkler, H., Gross, H., Sargent, D., Eppenberger, H. M., and Wallimann, T. (1990) Biophys J. 57, 420 and thus are suited for a detailed X-ray analysis in the future. The relatively high density of single crystals measured by a linear organic solvent density gradient indicates a tight packing of mitochondrial creatine kinase molecules within the crystals. Microcrystals, however, were subjected to electron optical examination either after prefixation with glutaraldehyde followed by conventional negative staining or by freeze-fracturing crystals in mother liquor and heavy metal replication with platinum/carbon. In both cases the crystals exhibited a square lattice with parameters of a = b = 139 A and a = b = 132 A in negatively stained and replicated crystals, respectively. No other lattice parameters were found, suggesting that these microcrystals represent a quasi-cubic three-dimensional lattice, which is in accordance with the finding that the building blocks of the crystals are the cube-like octamers described (Schnyder, T., Engel, A., Lustig, A., and Wallimann, T. (1988) J. Biol. Chem. 263, 16954-16962). Digital image processing applied to electron micrographs of crystals clearly revealed the arrangement of mitochondrial creatine kinase octamers in the crystal lattice as well as the subdivision of the octamer into its subdomains at a resolution of 23 A.

N-cadherin-associated proteins in chicken muscle

Abstract The development and functional activity of the heart depends on the regulated interaction of cardiac cells. This is in part mediated by cell-cell adhesion molecules such as N-cadherin. N-cadherin belongs to a family of Ca ++-dependent, transmembrane, adhesion glyco-proteins that promote cell-cell adhesion by molecular self-association extracellularly, and interact intracellu-larly with the cytoskeleton through highly conserved car-boxy-terminal domains. In this paper we show that embryonic chicken cardiac myocytes grown in vitro display Ca ++-dependent adhesion and express N-cadherin. When immunoprecipitated from detergent extracts of embryonic chicken cardiac and skeletal muscle cultures, N-cadherin associates with proteins immunologically unrelated to itself. The associated proteins are similar in molecular weight to proteins that coimmunoprecipi-tate with E-cadherin from human epithelial cells. We postulate that the coimmunoprecipitating proteins are involved in linking the cadherins to the cytoskele

The ultrastructure of patch-clamped membranes: a study using high voltage electron microscopy.

We have developed techniques for studying patch-clamped membranes inside glass pipettes using high voltage electron microscopy (HVEM). To preserve the patch structure with the least possible distortion, we rapidly froze and freeze dried the pipette tip. The pipette is transparent for more than 50 microns from the tip. HVEM images of patches confirm light microscopy observations that the patch is not a bare bilayer, but a membrane-covered bleb of cytoplasm that may include organelles and cytoskeleton. The membrane that spans the pipette is commonly tens of micrometers from the tip of the pipette and occasionally as far as 100 microns. The structure of patches taken from a single cell type is variable but there are consistent differences between patches made from different cell types. With suction applied to the pipette before seal formation, we have seen in the light microscope vesicles swept from the plasmalemma up the pipette. These vesicles are visible in electron micrographs, particularly those made from chick cardiac muscle. Colloidal gold labeling of the patch permitted identification of lectin-binding sites and acetylcholine receptors. In young cultures of Xenopus myocytes, the receptors were diffuse. In 1-wk-old cultures, the receptors formed densely packed arrays. The patch pipette can serve, not only as a recording device, but as a tool for sampling discrete regions of the cell surface. Because the pipette has a constant path length for axial rotation, it is a unique specimen holder for microtomography. We have made preliminary tomographic reconstructions of a patch from Xenopus oocyte.

Crystallization and preliminary X-ray analysis of two different forms of mitochondrial creatine kinase from chicken cardiac muscle

Crystals of mitochondrial creatine kinase isolated from chicken heart were grown by precipitation with polyethylene glycol 1000. The enzyme has been crystallized in the absence and presence of ATP in two different space groups. Crystals are tetragonal, with space group P42(1)2, a = b = 171 A, c = 150 A in the absence of ATP; and P422, a = b = 101 A, c = 114.4 A in the presence of ATP. We suggest that there is one octamer (346 kDa) per asymmetric unit without ATP and one dimer (86 kDa) per asymmetric unit with ATP. Using synchrotron radiation, the octameric form diffracts to at least 3 A resolution.

Electron Microscopic Comparison of Frozen-Hydrated with Negatively Stained and Rotary-Shadowed Creatine Kinase Single Molecules

The mitochondrial isoform of creatine kinase isolated from chicken cardiac muscle consists predominantly of an octameric protein species with an Mrof 364000 and a small fraction of a dimeric species (Mr=86000). Electron micrographs of negatively stained creatine kinase show the square-shaped octameric molecules (Fig. 3) and the banana-shaped dimers. Mass measurements of individual molecules by scanning transmission electron microscopy yield about 340 kDa for the octamer, and 89 kDa for the dimer. After freeze-drying and high-resolution shadowing the surface of the octameric molecules shows a distinct cross-like division into four units (Fig. 4). The image analysis with circular harmonic averaging reveals a pronounced four-fold symmetry of both the rotary-shadowed and negatively stained octamers.Unstained creatine kinase molecules are investigated with cryo-electron microscopy. The samples were diluted with buffer solution to about 1 mg/ml. Drops of the suspension were applied to glow-discharged holey carbon films, blotted to remove excess liquid, immediately plunged into partially solidified liquid ethane, and stored under liquid nitrogen until insertion into the microscope. The specimens were examined in the DEEKO 250 electron microscope, operated at 100 kV. Micrographs were recorded by minimum-dose methods at a magnification of 60000 and an underfocus of about 1000 nm (Fig. 1).

Functional studies with the octameric and dimeric form of mitochondrial creatine kinase. Differential pH-dependent association of the two oligomeric forms with the inner mitochondrial membrane.

Phosphate extraction of mitochondrial creatine kinase (Mi-CK, EC 2.7.3.2) from freshly isolated intact mitochondria of chicken cardiac muscle, after short swelling in hypotonic medium, yielded more than 90% of octameric and only small amounts of dimeric Mi-CK as judged by fast protein liquid chromatography-gel permeation analysis of the supernatants immediately after extraction of the enzyme. In extraction buffer, octameric Mi-CK displayed a tendency to dissociate, albeit at a slow rate with a half-life of approximately 3-5 days, into stable dimers. Experiments with purified Mi-CK octamers or dimers, or defined mixtures thereof, incubated under identical conditions with Mi-CK-depleted mitoplasts revealed that both oligomeric forms of Mi-CK can rebind to mitoplasts. However, the association of Mi-CK was strongly pH-dependent and, in addition, octameric and dimeric Mi-CK showed different pH dependences of rebinding. Therefore, it was possible under certain pH conditions to rebind either both oligomeric forms or selectively the octamers only. Furthermore, evidence is presented that Mi-CK dimers partially form octamers upon rebinding to the inner membrane. The differential association of the two oligomeric Mi-CK forms with the inner mitochondrial membrane together with the dynamic equilibrium between octameric and dimeric Mi-CK (Schlegel, J., Zurbriggen, B., Wegmann, G., Wyss, M., Eppenberger, H.M., and Wallimann, T. (1988) J. Biol. Chem., 263, 16942-16953) suggest that both oligomeric forms are physiologically relevant. A change in the octamer to dimer ratio may influence the association behavior of Mi-CK in general and thus modulate mitochondrial energy flux as discussed in the phosphoryl creatine circuit model (Wallimann, T., Schnyder, T., Schlegel, J., Wyss, M., Wegmann, G., Rossi, A.-M., Hemmer, W., Eppenberger, H.M., and Quest, A.F.G. (1989) Prog. Clin. Biol. Res. 315, 159-176.

Molecular Characterization of 1, 4-Dihydropyridine-Sensitive Calcium Channels of Chick Heart and Skeletal Muscle

A monoclonal antibody designated as MAC-L1 immunoprecipitated [3H]PN200-110-labeled calcium channels of chick cardiac and skeletal muscle. On specific immunoprecipitation of 125I-labeled proteins, two large polypeptides (Mr 197,000 and 139,000 for heart, and 172,000 and 135,000 for skeletal muscle, under reducing conditions) were identified as the major components of these channels. Both polypeptides were found to exist together as a complex in 1% digitonin, but to become separated from each other in 1% Triton X-100. The 197 and 172 kDa peptides of cardiac and skeletal muscles, respectively, were photolabeled with [3H]azidopine. Under nonreducing conditions, the 139 kDa polypeptide of heart and the 135 kDa polypeptide of skeletal muscle took on larger molecular weights of 192,000 and 190,000, respectively. The 139 kDa but not the 197 kDa component of the heart was capable of binding to wheat germ agglutinin-Sepharose. Among the polypeptides specifically precipitated by MAC-L1, a 165 kDa peptide of skeletal muscle was phosphorylated by cAMP-dependent protein kinase. In contrast, a minor 99 kDa polypeptide, but not the major 197 kDa polypeptide, of the heart was phosphorylated by this kinase. These results suggest that the dihydropyridine-sensitive cardiac calcium channel has alpha 1 and alpha 2 subunits that are homologous but not identical to those of the skeletal muscle calcium channel.

Monoclonal Antibody Assessment of Tissue- and Species-Specific Myosin Light Chain Kinase Isozymes1

Monoclonal antibodies raised against chicken gizzard smooth muscle myosin light chain kinase were used for immunological and structural studies of this enzyme. Epitope mapping of trypsin-digested chicken gizzard enzyme showed that MM-1, 2, 3, 4, 5, 6, and 7 bind to 65 kDa (trypsin-digested) and 60 kDa (chymotrypsin-digested) fragments which contain the catalytic domain of the kinase. Kinetic analysis demonstrated that MM-7 inhibited kinase activity competitively with respect to ATP and noncompetitively with respect to myosin light chain, thereby indicating that MM-7 binds at or near the ATP binding site of the enzyme. Immunoblot analysis revealed that all these antibodies (MM-1 to 12) reacted with the enzyme (130 kDa) from intestinal and vascular smooth muscles, whereas 5 (MM-1, 3, 4, 6, and 9) or 3 (MM-1, 3, and 4) of 12 antibodies did not cross-react with chicken cardiac muscle or with blood platelet myosin light chain kinase (130 kDa), respectively. None of these antibodies showed cross-reactivity against skeletal muscle myosin light chain kinase. As for mammalian species, MM-11 and 12 reacted with myosin light chain kinase of vascular smooth muscle (140 kDa) and MM-11 cross-reacted with the enzyme (140 kDa) from cardiac muscle of rat and rabbit. These data suggest the existence of at least 4 subspecies of myosin light chain kinase in chicken tissues and the heterogeneity of tissue- and species-specific isozyme forms.

Four exons encode a 93-base-pair insert in three neural cell adhesion molecule mRNAs specific for chicken heart and skeletal muscle.

The neural cell adhesion molecule (N-CAM) is detected in chicken brain as three polypeptides of 180 kDa, 140 kDa, and 120 kDa that arise from a single gene by alternative splicing. Heart tissue, however, contains components of 150 kDa, 140 kDa, and 130 kDa; neither the differences in molecular mass among these components nor the difference between neural and cardiac N-CAM could be accounted for by variations in glycosylation alone. A cDNA clone isolated from an embryonic chicken heart library, [lambda N101B, 1.8 kilobases (kb)] contained a 93-base-pair (bp) insert not found in neural N-CAM cDNAs. In the N-CAM gene this sequence mapped within a large region between exons 12 and 13 and was derived from four exons (12A-D) of 15, 33, 42, and 3 bp. Exons 12C and 12D together coded for 15 amino acids very similar to the second half of the muscle-specific insert (MSD1) found in N-CAM cDNA from human muscle cell cultures [Dickson, G., Gower, H. J., Barton, C. H., Prentice, H. M., Elsom, V. L., Moore, S. E., Cox, R. D., Quinn, C., Putt, W. & Walsh, F. S. (1987) Cell 50, 1119-1130]; the sequences of 12A and 12B, however, were much less similar to the corresponding region of the MSD1 sequence. Two oligonucleotides, one specific to exons 12A plus 12B and one specific to exon 12C both recognized mRNA species of 6.4 kb, 4.3 kb, and 3.0 kb in chicken cardiac and skeletal muscle and no mRNA species in smooth muscle or brain. The 3' end of clone lambda N101B contained a sequence coding for a potential phosphatidylinositol linkage signal as does the smallest form of brain N-CAM. In heart cell membranes only the 130-kDa N-CAM polypeptide was released by phospholipase C, suggesting that this form of N-CAM is encoded by clone lambda N101B. The other heart N-CAM species (150 kDa and 140 kDa) may be transmembrane forms that include the 12A-D (and possibly other) inserts. Tissue-specific forms of N-CAM can thus be formed by alternative use of multiple small exons that may alter the conformation of the extracellular region of the molecule. Differential use or switching of these small exons in conjunction with the differential expression of larger exons specifying regions associated with the cell membrane and cytoplasmic domains may signal key events in embryogenesis and histogenesis.

Native mitochondrial creatine kinase forms octameric structures. I. Isolation of two interconvertible mitochondrial creatine kinase forms, dimeric and octameric mitochondrial creatine kinase: characterization, localization, and structure-function relationships.

The mitochondrial isoform of creatine kinase (Mi-CK, EC 2.7.3.2) purified to homogeneity from chicken cardiac muscle by the mild and efficient technique described in this article was greater than or equal to 99.5% pure and consisted of greater than or equal to 95% of a distinct, octameric Mi-CK protein species, with a Mr of 364,000 +/- 30,000 and an apparent subunit Mr of 42,000. The remaining 5% were dimeric Mi-CK with an apparent Mr of 86,000 +/- 8,000. Octamerization was not due to covalent linkages or intermolecular disulfide bonding. Upon dilution into buffers of low ionic strength and alkaline pH, octameric Mi-CK slowly dissociated in a time-dependent manner (weeks-months) into dimeric Mi-CK. However, the time scale of dimerization was reduced to minutes by the addition to diluted Mi-CK octamers of a mixture of Mg2+, ADP, creatine and nitrate known to induce a transition-state analogue complex (Milner-White, E.J., and Watts, D. C. (1971) Biochem. J. 122, 727-740). The conversion was fully reversible, and octamers were reformed by simple concentrations of Mi-CK dimer solutions to greater than or equal to 1 mg/ml at near neutral pH and physiological salt concentrations in the absence of adenine nucleotide. After separation of the two Mi-CK species by gel filtration, electron microscopic analysis revealed uniform square-shaped particles with a central negative-stain-filled cavity in the octamer fractions and "banana-shaped" structures in the dimer fractions. Mi-CK was localized inside the mitochondria by immunogold labeling with polyclonal antibodies. A dynamic model of the octamer-dimer equilibrium of Mi-CK and the preferential association of the octameric Mi-CK form with the inner mitochondrial membrane is discussed in the context of regulation of Mi-CK activity, mitochondrial respiration, and the CP shuttle.

Mitochondrial creatine kinase from cardiac muscle and brain are two distinct isoenzymes but both form octameric molecules.

Mitochondrial creatine kinase (Mi-CK) from chicken cardiac muscle and brain, recently shown to differ in their N-terminal amino acid sequences and to be encoded by multiple mRNAs (Hossle, H.P., Schlegel, J., Wegmann, G., Wyss, M., Böhlen, P., Eppenberger, H. M., Wallimann, T., and Perriard, J.C. (1988) Biochim. Biophys. Res. Commun. 151, 408-416) were separated on two-dimensional nonequilibrium pH-gradient electrophoresis gels and visualized as two distinct protein spots by immunoblotting. Analysis of the two proteins purified by specific elution from Blue-Sepharose with ADP (Wallimann, T., Zurbriggen, B., and Eppenberger, H. M. (1985) Enzyme 33, 226-231) followed by fast protein liquid chromatography cation exchange chromatography showed obvious differences in peptide maps, in immunological cross-reactivity with monoclonal antibodies, and in kinetic parameters. However, even though the two proteins were different, tissue-specific mitochondrial isoforms, both formed regularly-sized, perforated cube-like octameric structures with Mr of 364,000 +/- 25,000 and 352,000 +/- 20,000 for the cardiac and brain isoform, respectively. Electron microscopy of cardiac and brain Mi-CK octamers revealed cube-like molecules with a central cavity or transverse channel filled by negative stain. The octameric molecular structure of Mi-CK isoforms differs from the generally accepted dimeric arrangement of "cytosolic" muscle MM- and brain BB-CK.

Identification of two variants of troponin T in the developing chicken heart using a monoclonal antibody.

Troponin T (TNT) expressed in the developing chicken cardiac muscle was examined by immunoblotting combined with two-dimensional electrophoresis (2-D PAGE) and peptide mapping. When the whole lysate of the neonatal heart was examined by 2-D PAGE, two TNT variants were detected on the gel by monoclonal antibody to TNT. Expression of the two variants was developmentally regulated: one isoform (type I) was expressed from embryonic through neonatal stages, and the other (type II) from the late embryonic stage through adulthood during cardiac muscle development. The type-I isoform, but not type-II isoform, was also expressed transiently in chicken skeletal muscle at embryonic stages. As judged from the peptide maps, the two isoforms differed in the N-terminal region but not in the C-terminal region.

Regulation of troponin C synthesis in primary culture of chicken cardiac muscle cells.

Cardiac myocyte cell culture from fourteen day old embryonic chicken heart was prepared. This cultured cell system was used to examine the regulation of troponin C (TnC) synthesis in cardiac muscle. To examine the regulation of TnC polypeptide synthesis, cardiac myocyte cells were pulse labelled with 35S-methionine at different days after plating. The synthesis of TnC was measured by determining the amount of radioactivity incorporated into the TnC polypeptide following separation by two dimensional gel electrophoresis. These measurements showed that TnC synthesis was maximum in 36 to 48 h old cultures and reached its lowest level in 4 day old cultures. This was in contrast to the synthesis of actin and tropomyosin. Synthesis of these polypeptides were lowest in 36 to 48 h old cultures and was maximum in 7 day old cultures. To examine whether the synthesis of TnC polypeptide paralleled the levels of TnC mRNA the sequences homologous to quail slow TnC cDNA clone were measured by hybridisation. The results showed that the decrease in the synthesis of troponin C polypeptide cannot be fully explained by the decrease in the steady state level of troponin C mRNA. The possibility of a role of translational control of troponin C mRNA in this process is discussed.

3-Methylhistidine content and pH dependency of ATPase activity of adult and embryonic chicken cardiac ventricular myosins.

A distinct difference in the 3-methylhistidine (3-MeHis) content and the pH-dependency curve for calcium-activated adenosine triphosphatase (Ca-ATPase) activity was observed between chicken and mammalian cardiac ventricular myosins. The 3-MeHis content and pH dependency of the Ca-ATPase activity of myosins from adult and embryonic chicken cardiac ventricular muscles and chicken fast white and slow red muscles were almost the same.

Expression of functional sodium channels from cloned cDNA

The voltage-gated sodium channel is a transmembrane protein essential for the generation of action potentials in excitable cells. It has been reported that sodium channels purified from the electric organ of the electric eel, Electrophorus electricus, and from chick cardiac muscle consist of a single polypeptide of relative molecular mass (Mr) approximately 260,000, whereas those purified from rat brain and from rat and rabbit skeletal muscle contain, in addition to the large polypeptide, one or two smaller polypeptides of Mr 33,000-43,000. The primary structures of the Electrophorus sodium channel and two distinct sodium channel large polypeptides (designated as sodium channels I and II) from rat brain have been elucidated by cloning and sequencing the complementary DNAs. The purified sodium channel preparations from Electrophorus electroplax and from mammalian muscle and brain, when reconstituted into lipid vesicles or planar lipid bilayers, exhibit some functional activities. The successful reconstitution with the Electrophorus preparation would imply that the large polypeptide alone is sufficient to form functional sodium channels. However, studies with the rat brain preparation suggest that the smaller polypeptide of Mr 36,000 is also required for the integrity of the saxitoxin (STX) or tetrodotoxin (TTX) binding site of the sodium channel. Here we report that the messenger RNAs generated by transcription of the cloned cDNAs encoding the rat brain sodium channel large polypeptides, when injected into Xenopus oocytes, can direct the formation of functional sodium channels.

Exchangeability of alpha-actinin in living cardiac fibroblasts and muscle cells.

We have investigated the exchangeability of alpha-actinin in various structures of cultured chick cardiac fibroblasts and muscle cells using fluorescent analogue cytochemistry in combination with fluorescence recovery after photobleaching. Living cells were microinjected with tetramethylrhodamine-labeled alpha-actinin, which became localized in cellular structures. Small areas of labeled structures were then photobleached with a laser pulse, and the subsequent recovery of fluorescence was monitored with an image intensifier coupled to an image-processing system. In fibroblasts, fluorescence recovery was studied in stress fibers and in adhesion plaques. Bleached spots in adhesion plaques generally attained complete recovery within 20 min; whereas complete recovery in stress fibers occurred within 30 to 60 min. In muscle cells, alpha-actinin became localized in the Z-lines of sarcomeres, in punctate structures, and in apparently continuous bundle-like structures. Fluorescence recovery in Z-lines, punctate structures, and some bundle-like structures was extremely slow. Complete recovery did not occur within the 6- to 7-h observation period. However, some bundle-like structures recovered completely within 60 min, a rate similar to that of stress fibers in fibroblasts. These results indicate that fluorescently labeled alpha-actinin is more stably associated with structures in muscle cells than in fibroblasts. In addition, different structures within the same cell can display different alpha-actinin exchangeabilities which, in muscle cells, could be developmentally related.

Phosphorylation of bovine cardiac C-protein by protein kinase C

C-protein, a thick filament-associated protein, has been isolated from bovine myocardium and found to be a substrate in vitro of the Ca 2+- and phospholipid-dependent protein kinase (protein kinase C). Incorporation of 1.6 mol P i/mol C-protein was observed. This phosphorylation was dependent on both Ca 2+ and a phospholipid (L-α-phosphatidyl-L-serine was used). Phosphate incorporation specifically into C-protein was verified by SDS-polyacrylamide gel electrophoresis and autoradiography and was almost exclusively into serine residues (86.9%), with only a small amount of phosphothreonine (13.1%) and no phosphotyrosine being detected. Two-dimensional thin-layer electrophoresis of a chymotryptic digest of phosphorylated C-protein indicated site specificity of phosphorylation. Cardiac C-protein is known to be a substrate of cAMP-dependent protein kinase both in vitro and in vivo (Jeacocke, S.A. and England, P.J. (1980) FEBS Lett. 122 , 129–132). Isolated bovine cardiac C-protein was rapidly phosphorylated, to the extent of 5 mol/mol, by the purified catalytic subunit of cAMP-dependent protein kinase. Phosphorylation catalyzed by these two protein kinases was not additive, suggesting that the sites phosphorylated by protein kinase C are also phosphorylated by cAMP-dependent protein kinase. Chicken cardiac muscle has also been shown to contain a Ca 2+, calmodulin-dependent protein kinase which phosphorylates C-protein (Hartzell, H.C. and Glass, D.B. (1984) J. Biol. Chem. 259 , 15587–15596). The physiological role of cardiac C-protein may therefore be subject to regulation by multiple protein kinases.

Phosphorylation of purified cardiac muscle C-protein by purified cAMP-dependent and endogenous Ca2+-calmodulin-dependent protein kinases.

C-protein, a component of the thick filament of striated muscles, becomes phosphorylated in response to beta-adrenergic receptor stimulation and dephosphorylated in response to cholinergic receptor stimulation in heart. We have purified C-protein in high yield from cardiac muscle (approximately 50% yield: 0.3 mg of C-protein/g of frozen chicken heart). C-protein has a molecular weight on sodium dodecyl sulfate polyacrylamide gels of 155,000 but the native protein migrates as a globular protein of 209,000 daltons in gel filtration on Sephacryl S-300, suggesting that it is an asymmetric molecule composed of a single 155,000-dalton polypeptide. C-protein from chicken cardiac muscle has an amino acid composition similar to that of C-proteins from other muscles. The purified protein contains approximately 0.2 mol of phosphate/mol of C-protein. The purified C-protein has no endogenous protein phosphatase activity but does exhibit protein kinase activity in the presence of calcium and calmodulin (approximately 160 pmol of phosphate incorporated/min/mg of C-protein). This endogenous kinase catalyzes the incorporation of approximately 1 mol of phosphate/mol of C-protein. C-protein is an excellent substrate for catalytic subunit of cAMP-dependent protein kinase (Km = 4 microM, Vmax = 18.6 mumol/min/mg). Phosphorylation by catalytic subunit of cAMP-dependent protein kinase exhibits a broad pH optimum between pH 8 and 9 and results in the incorporation of up to 3 mol of phosphate/mol of C-protein. Phosphate is incorporated into 3-5 different sites at both phosphothreonine and phosphoserine residues. The phosphorylated C-protein does not differ from unphosphorylated C-protein with regard to Stokes radius, migration on sodium dodecyl sulfate-polyacrylamide gels, or UV spectrum.